Your search keyword '"Zhi Hui Li"' showing total 356 results

351. Gas-kinetic numerical study of complex flow problems covering various flow regimes

Author

Han-Xin Zhang, Zhi-Hui Li, Lin Bi, and Lin Li

Subjects

Parallel computing, Hypersonic speed, Discretization, Discrete velocity ordinate method, Computational fluid dynamics, Physics::Fluid Dynamics, symbols.namesake, Modelling and Simulation, Mathematics, business.industry, Numerical analysis, Mechanics, Numerical integration, Boltzmann model equation, Computational Mathematics, Classical mechanics, Hele-Shaw flow, Mach number, Flow (mathematics), Computational Theory and Mathematics, Modeling and Simulation, symbols, Velocity distribution function, Finite difference computation, business, Three-dimensional complex flows

Abstract

The Boltzmann simplified velocity distribution function equation, as adapted to various flow regimes, is described on the basis of the Boltzmann–Shakhov model from the kinetic theory of gases in this study. The discrete velocity ordinate method of gas-kinetic theory is studied and applied to simulate complex multi-scale flows. On the basis of using the uncoupling technique on molecular movements and collisions in the DSMC method, the gas-kinetic finite difference scheme is constructed by extending and applying the unsteady time-splitting method from computational fluid dynamics, which directly solves the discrete velocity distribution functions. The Gauss-type discrete velocity numerical quadrature technique for flows with different Mach numbers is developed to evaluate the macroscopic flow parameters in the physical space. As a result, the gas-kinetic numerical algorithm is established for studying the three-dimensional complex flows with high Mach numbers from rarefied transition to continuum regimes. On the basis of the parallel characteristics of the respective independent discrete velocity points in the discretized velocity space, a parallel strategy suitable for the gas-kinetic numerical method is investigated and, then, the HPF (High Performance Fortran) parallel programming software is developed for simulating gas dynamical problems covering the full spectrum of flow regimes. To illustrate the feasibility of the present gas-kinetic numerical method and simulate gas transport phenomena covering various flow regimes, the gas flows around three-dimensional spheres and spacecraft-like shapes with different Knudsen numbers and Mach numbers are investigated to validate the accuracy of the numerical methods through HPF parallel computing. The computational results determine the flow fields in high resolution and agree well with the theoretical and experimental data. This computing, in practice, has confirmed that the present gas-kinetic algorithm probably provides a promising approach for resolving hypersonic aerothermodynamic problems with the complete spectrum of flow regimes from the gas-kinetic point of view for solving the mesoscopic Boltzmann model equation.

352. Nonlinear Rolling Motion of Damaged Warship Based on Cell Mapping Method.

Author

Hui Liu, Zhi-hui Li, Xiang-jun Wu, and Jin-yun Pu

Published

2020

353. Pressure-induced isostructural phase transition in α-Ni(OH)2 nanowires.

Author

Xin Ma, Zhi-Hui Li, Xiao-Ling Jing, Hong-Kai Gu, Hui Tian, Qing Dong, Peng Wang, Ran Liu, Bo Liu, Quan-Jun Li, Zhen Yao, and Bing-Bing Liu

Subjects

*NANOWIRES, *SEMICONDUCTOR nanowires, *PHASE transitions, *BULK modulus, *RAMAN spectroscopy, *AMORPHIZATION, *CRYSTAL structure

Abstract

High pressure structural phase transition of monoclinic paraotwayite type α-Ni(OH)2 nanowires with a diameter of 15 nm–20 nm and a length of several micrometers were studied by synchrotron x-ray diffraction (XRD) and Raman spectra. It is found that the α-Ni(OH)2 nanowires experience an isostructural phase transition associated with the amorphization of the H-sublattice of hydroxide in the interlayer spaces of the two-dimensional crystal structure at 6.3 GPa–9.3 GPa. We suggest that the isostructural phase transition can be attributed to the amorphization of the H-sublattice. The bulk moduli for the low pressure phase and the high pressure phase are 41.2 (4.2) GPa and 94.4 (5.6) GPa, respectively. Both the pressure-induced isostructural phase transition and the amorphization of the H-sublattice in the α-Ni(OH)2 nanowires are reversible upon decompression. Our results show that the foreign anions intercalated between the α-Ni(OH)2 layers play important roles in their structural phase transition. [ABSTRACT FROM AUTHOR]

Published

2019

354. Focusing properties of discrete RF quadrupoles.

Author

Zhi-Hui Li and Zhi-Jun Wang

Published

2017

355. Error analysis and lattice improvement for the C-ADS Injector- I.

Author

Cai Meng, Zhi-Hui Li, and Jing-Yu Tang

Published

2014

356. Mesoscopic Photonic Crystals Made of TiO2 Hollow Spheres Connected by Cylindrical Tubes.

Author

Yong-zheng Zhu, Hong-bo Chen, Yan-ping Wang, Zhi-hui Li, Yan-ling Cao, and Yuan-bin Chi

Subjects

PHOTONICS, CRYSTALS, TITANIUM dioxide, SILICA, SINTERING, SEDIMENTATION & deposition, BRILLOUIN zones

Abstract

The face-centered cubic (fcc) photonic crystals of titanium dioxide (TiO2) hollow spheres connected by TiO2 cylindrical tubes have been fabricated using silica template. The preparation process is based on the vertical deposition method, thermal sintering and selective etching techniques. In the crystal, the lowest energy pseudogaps at points U and K of the Brillouin zone have been opened. [ABSTRACT FROM AUTHOR]

Published

2006